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Hannon, Matthew (2016) Mission Impossible? Five Challenges Facing
'Mission Innovation', the Global Clean Energy Innovation Drive.
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Mission Impossible? Five challenges facing ‘Mission Innovation’, the global
clean energy innovation drive
Matthew Hannon, University of Strathclyde Chancellor’s Fellow of Technology and Innovation
Making a difference to policy outcomes locally, nationally and globally
POLICY BRIEF
The views expressed herein are those of the author
and not necessarily those of the
International Public Policy Institute (IPPI),
University of Strathclyde.
© University of Strathclyde
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 1
Mission Impossible? Five challenges facing ‘Mission Innovation’, the global clean energy innovation drive
Dr. Matthew Hannon, Strathclyde Chancellor’s Fellow of Technology and Innovation
Hunter Centre for Entrepreneurship, Strathclyde Business School
Introduction
In December 2015 the landmark Paris Climate Agreement was signed by 195 countries at the
21st Conference of the Parties (COP21)1. Covering the period from 2020 it obligates all parties
to take action to limit global temperature rise to less than 2°C above pre-industrial levels.
Interestingly, in comparison to previous COPs, there was a much stronger focus on the need to
accelerate low-carbon innovation in order to avoid catastrophic anthropogenic climate change
and wide-spread deliberation about how best this might be achieved. Consequently, to help
deliver the Paris Agreement targets, world leaders established Mission Innovation (MI)2; an
agreement between 21 regions to double their clean energy research and development (R&D)
investment by 2021 (Fig. 1). This commitment to innovation was matched by the private sector
through the Breakthrough Energy Coalition3, a group of 28 high net worth investors including
Bill Gates, Richard Branson and Mark Zuckerberg, who have all committed to expand their
energy investment portfolio.
Whilst MI is now underway, it is still at a relatively early-stage of development and faces a
number of key challenges that must be overcome if it is to be successful in delivering the next
generation of clean energy innovations capable of helping us simultaneously address the
energy trilemma of climate change, energy security and affordability - whilst also accelerating
economic growth. Consequently, this policy briefing outlines the major challenges it faces and
discusses how these could be addressed, but first considers the broad aim and structure of MI.
Figure 1: Mission Innovation is launched at the Paris Climate Summit (COP21) (Source: MI)
1 http://unfccc.int/paris_agreement/items/9485.php
2 http://mission-innovation.net/ 3 http://www.breakthroughenergycoalition.com/en/index.html
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 2
What’s the aim of Mission Innovation and who’s involved?
The central aim of MI is to double public sector clean energy R&D investment from
approximately $15bn per year in 2015 to $30bn per year in 2021 (Fig. 2)4. To achieve this aim
21 regions5 have committed to double their individual energy R&D budgets, and together these
account for well over 80% of global public investment in clean energy research, development
and demonstration (RD&D). Their common understanding is that whilst important progress has
been made in reducing the cost and increasing the deployment of clean energy technologies,
the pace of innovation remains significantly short of what is needed to avoid catastrophic climate
change.
Figure 2: Targeted public energy R&D investment 2016-2021 under Mission Innovation (Source: MI)
How will Mission Innovation work?
Whilst the structure of the MI is still evolving a general framework for action is now in place6,
which highlights the following:
1. Clean energy R&D - Investment must focus on ‘clean energy’ R&D. MI appears to take
a broad view of this includes, incorporating most forms of supply and demand-side
energy innovation other than unabated fossil fuel generation (Fig. 3). It therefore
includes fossil fuel R&D that supports greater efficiency or lower carbon consumption
4 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Country-Plans-and-Priorities.pdf 5 Australia, Brazil, Canada, Chile, China, Denmark, France, Germany, India, Indonesia, Italy, Japan, Mexico, Norway, Republic of Korea, Saudi Arabia, Sweden, the United Arab Emirates, the United Kingdom, the United States, plus the European Commission on behalf of the European Union. 6 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Enabling-Framework-1-June-2016.pdf
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 3
of fossil fuels. The focus on R&D also implies early- to mid-stage technology readiness
level (TRL) activity, i.e. not demonstration and pre-commercial deployment.
2. R&D priority identification - Each Member is required to independently select its own
priorities for clean energy R&D funding (Fig. 3) and the strategy it will employ to deliver
on these (i.e. polices, regulation etc.)7. In order to select these innovation priorities,
members are expected to employ rigorous analysis to identify gaps in their current
understanding of these R&D areas and develop a policy roadmap to address these8.
3. International collaboration - Members are encouraged to freely share information
between one another in relation to their energy R&D programmes and where mutual
interests exist, collaborate on joint research and capacity building9.
4. Private sector co-investment – There is a strong emphasis on members using their
increase in public sector R&D investment to leverage additional private sector
investment, not least through the Breakthrough Energy Coalition.
5. Not legally binding – Whilst the Paris Climate Agreement (COP21) constitutes a
legally binding global treaty, the MI framework does not and is instead a voluntary
arrangement.
Figure 3: Mission Innovation's member countries and their priority areas of energy R&D (Source: MI)
7 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Country-Plans-and-Priorities.pdf 8 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Sub-Group-on-Innovation-Analysis-and-Roadmapping-Summary-Update-May-2016.pdf 9 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Sub-Group-on-Information-Sharing-Summary-Update-May-2016.pdf
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 4
Five challenges facing Mission Innovation
Having outlined what MI aims to achieve and how is expected to function we now identify five
challenges that must be overcome if MI is to work effectively.
Challenge 1: Unprecedented increase in R&D investment during a period of decline
A doubling of clean energy R&D expenditure in 5 years represents an unprecedented challenge.
First, the target to double energy R&D comes at a time when energy RD&D10 investment has
fallen by almost a third ($5.5bn) between 2009 and 2013, one of the sharpest declines in support
over the past 40 years (Fig. 4). Second, whilst we have seen a doubling of clean energy RD&D
funding amongst MI members11 within 5 years before - between 1976 and 1980 - this period
saw a strong emphasis on fossil fuel innovation in reaction to the 1973 oil crisis. Whilst new
low-carbon technologies such as nuclear and wind energy emerged following a significant
increase in R&D investment during this period, it also saw a tripling of public investment in fossil
fuel energy12. Both innovation strategies were primarily focused on alleviating global reliance
on OPEC oil production by developing alternative energy technologies.
Energy RD&D also doubled more recently, between 1997 and 2009. However, this unfolded
over a 12 year period, a substantially longer period than that envisaged by MI. This period also
had a similarly strong focus on fossil fuel RD&D to the late 1970s, seeing investment increase
by almost a factor of 5 between 1997 and 2009. Whilst some of this fossil fuel R&D investment
is likely to have focused on lower carbon or more efficient fossil fuel technologies (e.g. combined
cycle gas turbines), R&D of non-fossil fuel technologies is considered a top priority in the future
if we are to avoid catastrophic climate change13.
10 IEA data is for RD&D not R&D, therefore including investment in demonstration not included in MI. 11 We include only the 12 MI members that the IEA provides RD&D data for, namely Australia, Canada, Denmark, France, Germany, Italy, Japan, Korea, Norway, Sweden, UK and United States. Data taken from http://wds.iea.org/WDS/Common/Login/login.aspx 12 This figure excludes CCS investment whilst Figure 4 includes all fossil fuel investment, both abated and unabated. This falls mainly into ‘oil and gas’ (e.g. ‘enhanced oil and gas production’, ‘refining, transport, storage of oil and gas’, ‘non-conventional oil and gas’ etc.) and ‘coal’ (e.g. ‘coal production, preparation and transport’, ‘coal combustion (incl. IGCC)’ and ‘coal conversion’. 13 http://www.iea.org/publications/freepublications/publication/EnergyTechnologyPerspectives2016_ExecutiveSummary_EnglishVersion.pdf
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 5
Figure 4: Public energy RD&D budget by technology 1974-2013 (Source: IEA)
In this context, policymakers are venturing into the unknown when we consider that no
international clean energy innovation strategy has ever been implemented on this scale before.
It is therefore critical that MI members share best-practice policy design to ensure that the
additional R&D funds are committed and invested as effectively as possible. This must be
sensitive to the wide spectrum of different approaches that can be implemented to support clean
energy innovation. For example, some countries adopt a centralised, government led, top-
down model, where collaboration is prioritised over competition and government laboratories
take the lead (e.g. Fraunhofer in Germany, RISO in Denmark). Other countries may opt for a
decentralised, market led, bottom-up model, where competition is prioritised over collaboration,
with start-ups and Original Equipment Manufacturers (OEMs) taking the lead. It also relates to
the balance of funding for ‘supply-push’ versus ‘demand-pull’ innovation support policies, as
well as whether the type of investment should differ for supply- versus demand-side energy
technologies and large-scale site assembled (e.g. nuclear) versus small-scale modular (e.g.
solar PV) technologies.
An honest exchange of the relative strengths and weaknesses of different innovation policy
strategies between MI members will be critical to its success. So too will be seeking lessons
on best-practice innovation policy from the OECD Directorate for Science, Technology and
Innovation14 and the wider academic innovation policy studies community.
14 http://www.oecd.org/sti/
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 6
Challenge 2: Balancing members’ investment as a proportion of their wealth
The target to double each member’s total public investment in clean energy R&D implicitly
assumes that all countries are currently contributing the same degree of effort to support energy
innovation and that a ‘flat rate’ doubling of public R&D investment is most equitable. This would
see a similar distribution of investment across the MI countries as in 2013 (latest year available),
with the US and Japan still contributing approximately 63% of the total public lean energy R&D
investment (Fig. 5). However, if we analyse MI members’ R&D investment as a proportion of
their national wealth we uncover a picture of some countries investing more in energy innovation
than others.
Figure 5 Public energy RD&D budget by country 1974-2013 (Source: IEA)
In relative terms, some countries are committing significantly more energy R&D investment as
a share of their GDP than others (Fig. 6). For example, if we take the period since the Kyoto
Protocol in 1997, the first legally binding climate change agreement, we find that Japan
committed $828 per $m GDP. This was almost three times as much as the US ($306 per $m
GDP) and eight times more than the UK ($110 per $m GDP)15. This raises important questions
about the equity and durability of MI, which is a non-legally binding agreement. Will MI members
be prepared to double their energy RD&D budgets when they know that others are committing
significantly less as a proportion of their wealth than others? Policymakers need to consider
whether those members who are committing the least clean energy R&D investment relative to
their wealth should be required to raise their level of support in line with their international peers.
Whilst this is likely to be politically challenging, given that it would penalise some countries at
15 Figure 6 includes all fossil fuel energy R&D investment. This is because MI includes ‘cleaner fossil energy’ as a priority area, which cannot be isolated within the IEA data because it is not clearly defined by MI.
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 7
the expense of others, it would lead to a ‘level playing field’ whereby each country is contributing
the same degree of effort to the global clean energy innovation drive.
Figure 6: Mission Innovation members’ public energy RD&D budgets as a proportion of GDP (Source: IEA)
Challenge 3: Clear understanding of relationship between reward and investment
Following on from ensuring a balanced distribution of investment amongst MI members it
follows that there should be a balanced apportioning of the benefits accrued from the innovation.
Assuming that members subscribe to the commitment to deliver joint-projects, then it is
important that each project member is absolutely clear about what proportion of the benefits
they will receive per $ of R&D investment they make and in what form these will be received
(e.g. licencing arrangements). Such an arrangement could follow a similar model as that
employed by high-profile publicly funded joint ventures like the International Thermonuclear
Experimental Reactor (ITER) nuclear fusion project, funded by the EU, India, Japan, China,
Russia, South Korea and the US16. Even so, multi-partner international R&D projects will
undoubtedly be contractually complex as each member is likely to be committing a different
level and type of investment. Efforts to develop standard contract templates and a more detailed
agreed working framework between MI members would certainly facilitate international
collaboration and help deliver clean energy R&D projects more quickly by keeping contractual
negotiations to a minimum.
16 https://www.iter.org/
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 8
Challenge 4: International and cross-sectoral co-ordination of R&D investment
International co-ordination of energy R&D funding across different technologies and stages of
innovation will be critical to developing the next generation of clean energy technologies. An
important question will be how the doubling of investment is distributed across the different
priority areas at a global level. This is complicated by that the fact that each MI member has its
own individual portfolio of R&D priority areas (Fig. 3) and has been committing R&D investment
to different areas of energy research (Fig. 7), together reflecting each member’s own interests
and capabilities.
Figure 7: MI members' public energy RD&D budgets 1997-2013 by country (Source: IEA)
Limiting global temperature rise to 2°C above pre-industrial levels demands that no single area
of clean energy innovation is neglected and so it is critical that members coordinate their support
to ensure this doesn’t happen (Fig. 8). To maximize the effectiveness of the increase in energy
R&D investment MI members should consider which countries are best-equipped to lead on
each R&D area and adopt a ‘best-with-best’ approach to collaboration. Furthermore, members
must also discuss which stage of innovation or technology readiness level (TRL) these should
investments focus on, for example basic research vs. pre-commercial demonstration.
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 9
Figure 8: Contribution of technology area and sector to global cumulative CO2 reductions (Source: IEA ETP 2016)
Cross-sectoral coordination will also be critical for similar reasons, i.e. to ensure that no single
priority area or stage of innovation benefits at the expense of others. Mechanisms such as the
MI’s Business & Investor Engagement Sub-Group17 will be critical to consolidate the partnership
between MI and the Breakthrough Energy Coalition, and ensure that key actors from both
sectors are clear which technologies and stage of innovation they are expected to support.
However, the private sector typically favours free market principles and is likely to resist a highly
coordinated strategy that constrains their freedoms.
Clear, objective and honest discussions between government and industry representatives
about how MI members should best coordinate investment across the different clean energy
priority areas will be critical to MI’s success. Proposals from MI’s various Sub-Group to develop
work programmes that inform future activities present an excellent start to achieving a
coordinated approach. However, it is essential these discussions are informed not just through
discussions within MI’s sub-groups but by wider debate across other relevant fora, not least the
Clean Energy Ministerial18, IEA Technology Collaboration Programmes (TCPs)19 and European
Energy Research Alliance (EERA)20.
17 http://mission-innovation.net/wp-content/uploads/2016/06/MI-Sub-Group-on-Business-and-Investor-Engagement-Summary-Update-May-2016.pdf 18 http://www.cleanenergyministerial.org/ 19 https://www.iea.org/tcp/ 20 http://www.eera-set.eu/
University of Strathclyde | International Public Policy Institute Policy Brief
October 2016 10
Challenge 5: Understanding the emissions reduction potential of Mission Innovation
It is currently unclear what level of carbon emissions reduction MI hopes to achieve. To ensure
global temperature rise is limited to less than 2°C above pre-industrial level it is important that
MI members analyse what level of decarbonisation could realistically be delivered by a doubling
of R&D investment across its portfolio of clean energy priority areas and how this tallies with
existing 2°C scenarios (e.g. Fig. 8). The International Energy Agency (IEA) is excellently placed
to deliver any additional systems-level modelling of how and when these MI R&D investments
could deliver carbon emissions reductions. Even so, this presents an excellent opportunity for
university researchers across the world to explore in-depth.
Conclusions
In conclusion, Mission Innovation represents a much-needed and timely initiative, one focused
on ushering in the next generation of clean energy technologies capable of helping the world
avoid catastrophic climate change. However, the initiative is still at an early stage and it faces
a number of important challenges that policy makers need to address if it is to be a success.
First, a doubling of clean energy R&D investment within 5 years during a period of declining
R&D public investment represents an unprecedented challenge. Its success will rely on MI
members sharing best-practice in energy innovation policy to ensure not only that this increase
is achieved but that investment is delivered effectively, leading to high-quality innovation
outputs.
Second, the political credibility and durability of a non-legally binding scheme is questionable
when it demands all countries to double their total clean energy R&D investment despite some
already committing significantly more investment as a proportion of their wealth than others (i.e.
$ R&D per GDP).
Third, a clear enabling framework must make clear the scale and type of benefit each MI
member will receive as proportion of their investment from multi-partner international R&D
collaboration.
Fourth, a combination of international and cross-sectoral coordination of R&D investment is
critical to ensuring a balanced distribution of investment across different clean energy priorities
and stages of innovation.
Fifth, MI members need to carefully consider the carbon emissions reduction potential of their
increased energy R&D investment in each priority area and how together these activities will
contribute to a 2oC future.
Taking these recommendations into account will undoubtedly help transform the ground-
breaking Mission Innovation from Mission Impossible to Mission Accomplished.
About the author: Matthew Hannon is the University of Strathclyde’s Chancellor’s Fellow of Technology and Innovation, and is acting as Co-Investigator for the UKERC funded project ‘Financing community energy: lessons learned and future innovations to deliver a low-carbon future’. Contact details: Dr Matthew Hannon Strathclyde Chancellor’s Fellow of Technology and Innovation Hunter Centre for Entrepreneurship Strathclyde Business School University of Strathclyde Glasgow Email: matthew.hannon@strath.ac.uk Tel: +44 (0)141 548 3993 Twitter: @hannon_matthew International Public Policy Institute (IPPI) McCance Building, Room 4.26 University of Strathclyde 16 Richmond Street Glasgow G1 1XQ
t: +44 (0) 141 548 3865 e: ippi-info@strath.ac.uk The International Public Policy Institute IPPI is the University of Strathclyde’s principal gateway to policy research expertise. IPPI has within it, several discrete policy centres: the Centre for Government and Public Sector Policy, the Centre for Health Policy, the Centre for Energy Policy, the Centre for Education and Social Policy and the Institute for Future Cities. IPPI draws on expertise from across all four Faculties of the University – Humanities and Social Sciences, Strathclyde Business School, Science and Engineering – and from highly experienced practitioners who work with the Institute. For more information, please see www.strath.ac.uk/research/internationalpublicpolicyinstitute
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